Can capping and compressing machine.



H. L. GUENTHER.

CAN GAPPING AND GOMPBBSSING MACHINE- APPLICATION FILED JAN.18, 1907.

8 SHEETS-SHEBT 1.

WITNESSES: //v mm A TTORNEYS No. 891,162. PATENTED JUNE 16, 1908. H. L. GUENTHER.

CAN OAPPING AND COMPRESSING MACHINE.

APPLICATION FILED JAN. 18, 1907.v

8 SHEETS-SHEET 2.

A TTOHNEYS No. 891,162. PATENTED JUNE 16, 1908. H; L. GUENTHER.

GAN OAPPING AND GOMPRESSING MACHINE.

APPLICATION FILED JAN.18, 1907.

a SHEETS-SHEET a.

.Z (Yu i/7 ATTORNEYS FATENTED JUNE 16, 1908.

H. LIGUENTHER. CAN UAPPING AND GOMPRESSING MACHINE.

APPLICATION FILED JAN.18, 1907.

8 SHEETS-SHEET 6.

r e. m w m H r n w e n mu m Z r 7 4 PATENTED JUNE 16, 1908.

H. L. GUBNTHER. CAN OAPPING' AND GOMPRESSING MACHINE.

APPLICATION FILED JAN. 18, 1907.

a SHEETS-SHEET a] /N YEA/TOR .Hanrylllaeui/zer A TTOHNEYS No. 891,162. PATENTED JUNE 16, I908. H. L. GUENTHER.

CAN OAPPING AND GOMPRESSING MACHINE. APPLICATLON FILED JAN. 18, 1007.

s SHEETS-SHEET 7.

F E W BY w& 'W' 1 Arron/Us No. 891,162. PATENTED JUNE 16, 1908;

H. L. GUENTHER.

CAN UAPPING AND OOMPRBSMNG MACHINE. APPLIOATIUN FILED JAILlB, 1907.

8 SHEETS-SHEET 8.

. N VE/V TOE Jfcvzry 15.6; Rani/a er ZO/WWWWZJ A TTORNEYS ment on the line 55 of Fig. 1; Fig. 6

PATENT -hFIC.

HENRY LOUIS GUENTHER,

OF ILWAOO, WASHINGTON.

- oAN oarrme AND COMPRESSING MACHINE.

Specification of To all whom itmcty concern:

Be; it known that I, HENRY LOUIS GUEN- THER, a citizen of the United States, and a resident of Ilwaco, in'the county of Pacific and State of Washington, have invented a new and ImprovedCan Ca ping and Com- I pressing Machine, of which t he following is a full, clear, and exact description.

The inventionrelates to machines for capping and compressing cans, such as shown and described in Letters Patent of the UnitedStates, No. 698,701, granted to me April 29, 1902.

The object :ofthe presentinvention to provide a new and improved can capping and compressing machine which is simplified in construction, is very effective and wholly automatic in operation, and arranged for capping and com ressing the heads on can bodies and doub e-seaming the flanges to render the can perfectly air-tight, without the use of solder or other fastening means, packings or the'like, to-permit use of'the can n packing various food products.

The invention consists of novel features and-parts and combinations of the same, which will be more fully described herein afteriand then. pointed out in the claims.

I A practical embodiment of'the invention is represented in the accompanying drawings forming a part of this specification, in which similar characters of reference indicate corre- "sponding parts'in all the views.

Figure l is a plan view of the improvenient; Figg'Z is a front elevation of the same; Figfi 3 is a sectional front elevation of the same on theline 3-3 of Fig. i; Fig. l-

a side elevation of the left side of the machine; Fig. 5 is a transverse section of the improve- 13 a similar view of the same on the line 66 of Fig. '1; Fig. 7 is a sectional plan view of the improvement on the line 7 7 of lfig. fl Sis'a cross'section of the shifting mechanism for the push rods, on the linew8'8 of Fig. 3; Fig; 9 is-a transverse section of the crimping device; Fig. 10 is an enlarged sectional side elevation, on the-line 10-l0 of-Fig. 9, of the crimping-device, showing the can body and head about to be assembled; Fig. 11 is a horizontal section showing the can body and headfassembled; Fig. 12 is a similar view, showing the can body and head crimped together; Fig. 13' is a sectional side elevation a modified form of mandrel; and Fig. 14

Letters Patent. Patented June 16, 1908.

Application filed. January 18, 1907. Serial Nil. 352,882.

is a similar view of another modified form of mandrel.

In the improved machine presently to be described in detail, the can bodies are succ'essively fed by a feed mechanism to a vertically disposed rotating platen, and by a separate feed mechanism can heads are brought to the side of the can bodies and are engaged by a set of rapidly revolving mandrels and spindles to rotate the can body and its head in the platen, so that a crimping roller which now hngages the flanges of the assembled .can body and its head, forms a double seem, the platen next bringing the crimped can to a second set of rotzilting man drels and spindles, to rotate the crimped can and cause a compressing roller to press the double seam, to render the can body completely air-tight. To accomplish thiaresult in a simple manner, 1 construct the machine as follows: The improved machine is mounted on a suitably constructed frame A, on which is mounted the shaft B carrying a vertically disposed platen B revolvingintermittently in the direction of the arrow (1 and having in its periphery notches B for re- C, and on the front of the said platen B is arranged a can body feed mechanism D for successively feeding the can body 0 to the notches 2 register at the time ith the forward end of the said can body feeding mechanism, the said platen. a can body being intermitton' bring the next notch B in re forward end of the can bod anism D and to bring the can bod i spravious notch L in register with a can head feeding device E, forholding a can head Q over the end of the said can body C in the platen B. The registering can body (1 and its head. C are now located. between a rap idly revolving mandrel F and a rapidly receiving and holding a cylindrical can body volving'spimlle Pi arranged horizontally and v in axial alinement with each other, the said mandrel F and spindle H serving to rotate the can body C and its head C in the platen notch subject the double seam C to the action of a compressing roller J, to render the same all? I is circularly edged and proivided with clamp?- Fig. 5).

tight. The platen B finally brings the finished can to an ejecting d'evice K for clelivering the can from the machine at there'ar side of the platen.

In detail the construction-of the machine is as follows: The platen B is provided with ei'ght peripheral notches B, and each notch ing rings 13, having the end rounded off for the convenient entrance and. exit of the can bodies and. the finished cans, as hereinafter more fully described. A guard L extends over the top peripheral portion of the platen B to hold the can bodies in the notches B of- On the left hand end of the shaft B carrying the platen B is secured a spur wheel N in mesh with a pinion N secured on a short shaft bl journaled in suitable bearings in the main frame Ayand on the said shaft N is secured a detent wheel N formed with four radial recesses N, and it's peripheral surface is provided with segmental notches N The recesses N are adapted to be engagediby-a friction roller N 'journaled on the free end of an arm N secured on a horizontally disposed shaft N journaled in suitable bearings on the main frame A. On the shaft N 8 is secured a locking disk N having a segmental notch N on its peripheral surface, for engaging the periphery of the detent wheel N 3 during the time the friction roller N 6 travels in a recess N. During the time the friction roller N is out of a recess N 4 the remaining peripheral portion of the disk N travels in a segmental notch N so as to prevent the detent wheel N 3 from accidentally rotating during the period of rest, as shown in Fig. 4. I

The shaft N is rotated continuously and is provided for this purpose at its left hand end. with a gear wheel N. in mesh withla spur wheel N secured on a shaft N journaled in suitable bearings on the main frame A. At the left hand end of the shaft N 'is secured a ulley N connected by a belt N with a pu ey N secured on a shaftN journaked in suitable bearings in the main frame "A. The shaft N is driven from the main shaft 0 by gear wheels 0', O andh (see Fig. 4), and the right hand end of the driving shaft 0 is provided with the usual fast and loose pulleys 0 ()connected by belt with other machinery for im sitting a rotary motion'to the said main shaft 0.

Thd rbtatibn of the latter causes the rotation of the shaft N, which in turn rotates the shaft N by the pulleys N, N and the belt N and the rotary motion of the shaft N is transmitted by the pinion N and the gear wheel N to the shaft N which by the arm N and the friction wheel Ni intermittently rotates the detent wheel N and its shaft N connected by the pinion N and the gear wrheel N to the shaft B of the platen B. Thus when the main shaft 0 is rotated an intermittent rotary motion is given-to the platen B, and the gearing described is so proportioned that when the main shaft 0 makes one revolution the platen B makes oneeighth of a revolution, so that a succeeding notch B occupies the position the previous notch had, the platen being locked in position during the period of rest by the disk N, the peripheral surface of which travels in a segmental notch N of the detent wheel N.

The gear wheel N above mentionedalsd meshes with an intermediate gear wheel P (see Fig. 4) ininesh with a gear wheel P secured on a cam shaft P journaled in suitable bearings arranged on the top of the main frameA.

The can body feeding mechanism D is'next to be considered. This feeding device D is provided with a chute D down which travel the can bodies 0 by their. own weight, the

can bodies being fed into the upper end of the chute by hand or by mechanical means. The lowermost of the can bodies C in the chute D is pushed out of the chute into the notch B in register at the time with the delivery end of the said chute D. The base D of the chute D is mounted to slide in a .guideway D secured to or formed on the main frame A, and the said base D is engaged by a screw rod D mounted to turn in a bracket A attached to the main frame A. Now when the screw rod D is turned by an operator, the chute D is caused to slide up or down according to the'direction in which the screwirod D is turned, so that the de' livery end of the chute D is moved into accurate position relative to the platen notches B to allow the can body to bereadily pushed into the notchB registering at the time with the delivery end of the chute D. After the desired adjustment of the chute D 'mountedto slide transversely in guidewa'ys is made the base D thereof ispermanently it}? is secured another arm a.

"frame A, the other arm of scales D secured to the mainframe A. The push head 1) is provided at its top with an. out wardly extending arm I)" (see Fig. 5) adapted to pass under the next can bodyO above the one pushed out of the lower end of the, chute D at the time (so that-the can bodies can bodyreaches the bottom of the chute D so as to be in position to be pushed into the next succeeding notch B of the platen B.

The slide D for the push head D is piv-- otally connected by a link. Q with a similar slide K reciprocating in a guideway K secured to the main frame A, and on the slide is secured a push head. K extending in the delivery guideway K and serving to push aiinished can out of the corresponding notch B registering at the time with the in her or beginnim end of the guidi-zway K for delivering the finished can to one side of the machine. The delivery guideway 11* is pro vided with a slide K mounted to slide up and down in vertical guideways K secured to or formed'on the main frame A. (see Fig. 5), and the slideK is engaged by an adjusting screw rod K mounted to turn in bearings on the mainv frameA; Thus on turning the screw rod K the guideway K is raised or lowered. to bring it in proper position relative to the latch notch B carrying thefmished can to ejected by the push head K After the desired adjustment of the guideway K is made it is permanently fastened. in place by tap bolts K extending through elongated slots in the slide and screwing in the 'uideway K;

The link Q is pivotally connected with the free end of an arm Q secured on. a rock shaft, Q journaled in suitable bearings carried by the bracket A, and on the said rock shaft pivotally connected by sectional link Q" with one arm of a bell crank iever fulcrumed on the main the said bell crank leverQ carrying a friction roller Q, traveling in a cam groove f ormeo. on one face of the cam disk Q secured on the cam shaft P previously referred to. wi hen the cam shaft P is'rotated the cam'disk Q acts on the friction roller Q to impart a swinging motion to the bell. crank lever Q which lay the link Q and the arm Q rocks the shaft and the iatter by the arm Q, imparts a transversereciprocating motion to the link Q, which in turn reciprocates the push heads D and K simultaneously.- Normally the push heads D and K are in the position indicated in Fig. 5, and when the shaft Q is rocked then the push head D pushes the lowermost can body 6 out of the chute D into the notchB registering at the time with the lower end of 'neXt lowermost can head push head E.

the chute l), and at the same time the other push head ii pushes a finished can out of the nolchfB" registering at: tlietii'ne with the guideway' K. The push lie-ads D and K thenre'turn to their nornrai position of rest indicated in Fig. 5. The liiilfQt'is made in sections to allow proper "adjustment with the view to bring the push heads D; K in proper relation relativeto the can body (1. and "the finished cans.

The canhead feeding device E is arranged as follows: The can heads C pass down a chute E terminating at its bottomin a lateral chute E bolted or otherwise fastened to the main frame A, and the forward endof the said lateral chute E has the extreme end of its bottom curved upwardly to form a-stop and'the chute is provided with-side'openings E in register with the platen notch B con taining a can body ('3, so as to bring a can body and a can head in register with each other (see Figs. 9 and 10). The lowermost can head if" in the chute E is pushed into the cyluiider E by the use of a reciproeating push head E similar to the push heads D and K previously referred to, arid the said push head E" is held on an arm E secured to a slide E mounted to slide in suitable bearings E attached. to the main frame A (see Fig. 6.) The push head-E is provided on its top with an outwardly-extending arm E adapted i'o pass under the v C .in' the chute E", to hold the can heads C temporarily in position in said chute while. the lowermost can head is pushed into the cylinder by the push head WVhen the push head E returns to its normal position of rest shown in Fig. 6, then the can heads (7 in theichute E drop and the lowermost can headi now passes into the lateral chute E", to be next pushed into the end of the chute by the The slide E is pivotally connected by adjustable link It with an arm R secured on rock shaftit ournaled in suitable bearings A attached. to the main frame A.

Onthe rock shaft R (see Fig. 3) is securedv an. upwardiy extending arm R connected by a link R with one arm of a bell crank lever R fulcrumed on the main frame A; and car rying at its other arm a friction. roller-R (see Fig. 5) in a cam R secured on the cam shaft P. Now when the machine is running and the cam shaft P rotatedfthe cam Bland friction roller R impart a swinging motion to the bell crank lever B, which by the link R and arm R rocks the shaft R and the latter by the arm R and link R reciprocates the slide E and consequently the push head .E, for the latter to push the lowermost can. head C into tl'ie'end of the chute and then return to its i'iornial outermost position of rest as A. arm F pivotally connected by a link F with a horizontally extending lever F fulend of the chute E for engaging-the can head C One side ofthe end of the "chute E is provided with an opening E (see Fig, 9).-for entranceof the peripheral edge of the crimping roller I to permit of crimping the f1anges C 0 to form a double seam C" (see Fig. 12), and'which double seam C is .subsetpiently compressed by the compressing rol er J to form an air-tight seam without the use oflsolde'r. v

The revolving niandrels F, F and the spindles H, H shown in Fig. 7 are similar in construction and operation to the ones shown and described in the Letters Patent of the United States above referred to. The mandrels F and F are alike in construction and each is provided with a head F for en gaging the end of the can body C opposite the one receiving the can head C. Each head F is secured on a shaft F mounted to turn and slide horizontally in suitable bear ings on-the main frame A. Each of the two shafts F carries a gear wheel F in mesh with an idler gear wheel F 5 mounted to turn on a stud secured in the main frame A, the width of this gear'wheelF being somewhat in excess of that of the gear wheels F, so that the latter can move horizontally with their shafts F Without moving out of mesh with the gear wheel F The gear wheel F for the shaft F of the mandrel F" is in mesh at its top with a gear wheel 0 secured on the main driving shaft 0. Thus. when the machine is in operation and the driving shaft 0 rotates, it transmits a rotary motion by the gear Wheel to the gear wheel F for the shaft F of the mandrel F, and as this gear wheel is in mesh with the idler gear wheel F and the latter meshes with the ear wheel F on the shaft F for the mandre F, itisevident that both mandrels F and F are simultaneously and uniformly rotated.

In orderto impart a horizontal sliding motion-to the shafts F a transversely extending shifter bar F is employed and engages shifting collars F secured on the shafts F andthis shifter bar F is hung at its ends in arms F secured to a rock shaft F journaled in s'uitable bearings on the'main frame The rock shaft F is provided with an crumed on the. main frame and the said lever F is provided at its front end with a frictionroller engaging a cam-groove in a cam disk F attachedto'ithe cam shaft 1 I When the machine is in operation and the cam shaft P rotates then the cam F imparts a rocking motion to the lever F which by the link F imparts a swinging motion to the arm F thus rocking the shaft F The motion of the rock shaft F causes a swinging of the arms F", whereby the shifter bar F is moved horizontally, to shift the shafts F forward and backward and consequently the mandrels F, F, so that the faces of the heads F of the .mandrels move in contact with the edges of the can bodies. I

The spindles H and H are also alike in construction and operation, and hence it is suflicient to describe but one in detail.

Eachof thespindles H and H is provided with a spindle head H? (see Figs. 7 and 10) attached to the horizontally disposed shaft H mounted to-turn in suitable bearings in the main frame A but held against sliding movement therein. On the shafts H of the two spindles H and H are secured the gear wheels 0 and O in. mesh with the gear wheel N previously mentioned and secured on the shaft N so that when the main shaft 0 is rotated a simultaneous rotary motion is given to the shafts H of the two spindles H and H so as to run the same in unison with the mandrels F and F. The shafts H of the mandrels H and H are made hollow to receive push rods T, T provided with heads T adapted to engage the can head C at the center thereof, to push the can body 0 with the crimped or pressed seam free from the head H and out of the cylinder E the can body C sliding in the clamping ring B of the platen B until the flange C a'buts against the left face of the platen (see Fig. 7 The push rods T are reciprocatedby a shifting bar T (see Fig. 8) hung on arms T secured to and depending from a rock shaft T j ournaled in suitable bearings carried on the main frame A, and on the said rock shaft T is secured an arm T (see Fig.- 3) connected by. a link T with a lever T fulcrumed on the main frame,

and having a friction roller engaging a cam groove in. the face of a cam d sk T secured on the cam shaft P. Thus when the machme is in operation and the-cam shaft P is rotated the cam disk T imparts a'swinging motion to the lever T and by the link T and arm T causes a rocking of the rock shaft T, which by the arms T and the shifting bar T causes the push rods T and T to slide in the shafts H while the latter are rotating.

The crimping roller I and the compressing nected with, links 1 J having sliding connections with links I J pivoted' to the levers 1 J respectively, and between adjustable cross-heads in the said links I I and J J are mterposed the sprlngs I, J. The is vers P, J are fulcrumed on the mam frame and carry at their free ends friction rollers I, J engaging grooves in cam disks I, J secured on the cam shaft P. Thus when the machine is in motion and the cam shaft P is rotated the cam disks I J 7 simultaneously im art a swingingmotion to the levers I J 2 w mentioned are moved up and down together, to impart a swinging motion to the bell crank levers I, J, to move the crimping roller I against the flanges of the assembled body 0 and can head C, to form a double seam, and at the same time the compressin rollerJ presses the double seam of the crimpe can and renders the seam completely airtight, without requiring packing of any kind to prevent leakage when the can is used.

screw rod U by a wrench or The construction and operation of the crimp-v ing roller I and the compressing roller J is the same as described in the Letters Patent ,of the United States above referred to, so that further detail description of the same is not deemed necessary, it, however, being understood that when the machine is in operation a can after being crimped by the roller I is moved during the next two-eighths of a rev'o' lution of the platen B to the compressing roller J, for compressing the seam 0* made by the crimping roller I, which latter has its peripheral surface formed with an annular groove- (see Fig. 9) to cause the flanges C C to turn downward and inward with the- Wider flange C on the outside of the flan e C the latter doubling up to form a doubie seam C. This double seam C is subjected to greater pressure by the compressing roller J which has a straight peripheral face (see Fig. 5). The can thus finished is during the next one-ei hth revolution brought to the ejecting device K which removes t e finished can from the platen B.

The ivot pins U, U each helld on a plate U held vertically adjustable on the frame Aby ascrew rod U mounted to turn in a suitable bearing U attached to the frame A (see Fig. 5). Nowb turning the 'ke tool the plate U and pivot U or U can be raised or owered to brin the crimping roller I or the com ressing rol er J in proper relation to the 'can ody and can head anges C C IVhen the desired adjustment is made the plate U is permanently fastened in place by tap bolts U extending through dles H, H a lockin device is rovided consisting essentially o a bell cran lever V fulcrumed on the bracket A and having a lug engaging a corresponding notch B inthe peripheral surface of the platen B. The bell crank lever V is connected by a link V (see Fig. 5) with'an arm V secured on the ereby the yielding connections above mentioned are elongated slots" U in the plate U andscrewing in the main frame A.

rock shaft V journaled in suitable bearin s on the main frame A. On the rock shaft 1* is secured'an arm, V carrying a friction roller V ei'igaging' a cam groove in a cam disk V secured on the cam shaft P, so that when the latter is rotated the said cam disk 7 imparts a swinging motion to the arm V to rock the shaft V thus causing the arm V and link V to impart a swinging motion to the bell crank lever 'V. By this movement of the bell crank lever V its lug V is moved in and out of engagement with the corresponding notch B*, that is, during the period of rest of the platen B, the lug V and'1mmediately previous to impartin 'an intermittent rotary motion to the p aten B. The said bell crank lever V is extended so as to move the lug V outof engagement with the notch B ,.to unlock the laten B, and allow the same to turn one-eig th of' a revolution so as to bring the next following notch opposite the lug V.

The operation is as follows: When the platen B is at rest the several parts are in the position shown in Figs. 1-7 with the lowermost can body to be pushed by the head D into the first notch B of the platen and with a can body and can head in the second notch B of the platen for crimping, and the lowermost can iead C in the chute E, to be next ushed into the end of the chute by the us 1 head E. At the same time a crimpe can isin the top notch B of the platen and another crimped can is in the notch B at the compressing device and a finished can is opposite the ejecting device K to be ushed out of the notch B by the push hea K The mandi'els F, F and spindles H, II are now rotating and the crimping roller I en ages theflanges C and C of the can body at the crimping device, to crimp the said flanges and form a double seam. At the same time the double seam of the crimped can at the compressin device is pressed by the compressing roller J so as to render the seam airtight, it being understood that during the crimping and compressing operations the can bodies and their heads are revolved at a hi h speed while the crimping roller I and tie compressing roller J are held with a uniform pressure against the seam of the can: While this takes place the push "heads D and K are moved simultaneously from the right to the left, so that the lowermost can body C in the chute D is pushed into the front notch B of the platen by the ush head D", and the finished can is pushed h from the rearmost notch B into the guideway K which delivers thefinisfTzied can to oneside of the machine. The pushheads D and K then immediately return to their normal position of rest.

After the crimping and compressing operations are completed the rollers I and J move 0 in'the chute D in, position y thepush head K chute, as previously out of contact with the seams C of the corresponding cans and then the pusher rods T, T are caused to slide from the left to the right, to shift the cans bodily in the corresponding retaining rings B of the platen B until the scams 0" abut against the left face of the platen B. It is understood that when a can body C reaches the crim ing device the mandrel F first shifts or us 1es the can body C from the right to the eft so that the left end of the can body C enters the end of the explained, and when a can reaches the compressing device the mandrel F pushes the can from the right to the left until the canhead C is engaged by the spindle H, the can body being then rotated by the mandrel F and spindle H at the crimping device.

When the crim ing and compressing action is completed t 1e platen B is unlocked by disengagingthe lug V from the notch 13 after which an intermittent rotary motion is given to the platen B, and the latter is again locked in place after it has made one-eighth revolution bythe lug V engaging the next notch B The above-described operation is again repeated.

' position relative to Having thus described my invention, I I claim as new and desire to secure by Letters comprising a curved p'us the body on the wheel from the f The faces of the mandrel heads F may be plain, as' shown in Fig. 7, or provided with circular offsets F and F (see Figs. 13 and 14). The offset Ft is for use on can bodies 0 en at both ends and is adapted to pass into tl fe can body C,'to hold the same in a central position relative to the spindles H, H; The offset F is used on cans already closed by a head 0 on the right hand end, and this offset F is recessed to fit an offset on the can head C of a can for holding the latter in a central the spindles H, H.

Patent:

1. In a can capping and compressing ma chine, comprising a vertically disposed intermittently rotating platen having retainers in its peripheral suritace to receive and support the can bodies horizontally, of a can body feeding mechanism for periodically delivering the can bodies to the said retainers, said feed mechanism comprising a chute, .a slide movable through the bottom of the-chute and provided with a curved bar for engaging the lowermost body and with a rearward projection at the topof the bar for supporting the remaining bodies during the removal of the lowermost one, an'e'ecting mechanism op osite side of the platen eed mechanism, means for operating said feed mechanism, a'connection between the feed mechanism and the ejecting mechanism, whereby the feed mechanism will operate said ejecting mechanism, means for feeding can heads to the bodies, and

means for securing the heads to the bodies.

to the sai bar for engaging.

2. In a can capping and chine, comprising a vertically disposed intermittently rotating platen having retainers in its peripheral surface to receive and. support the can bodies horizontally, of a can body feeding mechanism comprising a chute, a slide movable through the bottom of the chute and provided with a curved bar for engaging the lowermost body, and with a rearward projection at the top of the bar for supporting the remaining bodies during the re moval of the lowermost one, an ejecting mechanism for engaging the bodies on the opposite side of the platenwheel from the feed mechanism, means for operating said feed mechanism, a connection between the feed mechanism and the ejecting mechanism, whereby the feed mechanism will operate said ejec'ting mechanism, means for feeding can heads to the bodies, and means for se curing the heads to the bodies.

3. In a can capping and compressing ma chine, comprising a vertically disposed intermittently rotating platen having retainers in its peripheral surface to receive andsupport the can bodies, of a can body feeding mechanism for )eriodically delivering the bodies d retainers, said feed mechanism comprising a chute, a slide movable through the bottom of the chute and provided with a curved bar for engaging and supporting the lowermost body, means in connection with the bar for supporting the remaining bodies during the removal of said lowermost one, an ejecting device for engaging the bodies on the opposite side of the (platen wheel, means for operating said feed e'vice and said ejecting, device in unison, means for feeding can heads to the bodies,'and means for securing the heads to' the bodies.

4. In a can capping andcompressing machine, comprising anintermittently rotating platen having retainers in its peripheral surace to receive and support the can bodies, of a can body feeding mechanism for periodically delivering the can bodies to the said retainers, com rising a chute for receiving the bodies, a s ide movable through the bottom of the chute, said slide having a curved bar for engaging the can body, and a rearward extension at the top of the bar for su porting the can bodies in the chute duringt .e

removal of the lowermost body,-ineans for operating the slide at predetermined intervals, means for feeding caps to the bodies, and means for securing the caps, to the bodies. I

5. In a can capping and compressing ma chine, comprising a vertically disposed inter mittently rotating platen having retainers in its peripheral surface to receive and support the can bodies horizontally, a canbody feed .ing mechanism for periodically delivering the can bodies to the said retainers, a can head feeding mechanism for periodically feeding a compressing masecures at the lower end thereof and with a side 0 ening adapted to register with a retainer of the laten, a push. head movable through the ateral extension and provided at its upper end with an arm for supporting the upper can heads when the lower head is removed, means for moving the can body through the retainer into contact with the head, means for securing the head to the body, and means for o ierating the head feeding means,

6. a can capping and compressing machine, a vertically disposed intermittently rotating laten having retainers in its periph eral su ace to receive and support can bodies, a can body feeding mechanism for periodically feeding can bodies to the said retainers, acan head feeding mechanism for periodically feeding a can head'to the end of a can body-in a retainer, said mechanism comprising a chute for receiving the can heads, said. chute having a lateral extension provided with-a stop at the lower end thereof,

and a side opening adapted to register with a retainer of the platen, a push head movable through-the lateral extension for removing the lowermost head, means for moving the this 55 can body through the retainer into contact with the head, means forsecuring the head to thebody, and means for operating the head feeding means. i

7 In a can capping and compressing ma chine, a can head feedmg mechanism, comprising a vertical chute having a lateral extension terminating in a sto and provided with'sideopenings and a pus head movable through the lateral. extension and provided with an arm for supporting the upper can headswhen the lower head is removed.

8. Ina can capping and compressing machine, the combination with a retainer for the can body, of a can head feeding mechanism, comprising a chute having a lateral ex tension terminating in a stop and being provided with side openings, adapted to register with the retainer, a push head movable through the lateral extension for removing the lowermost head and means for moving the can body through the retainer into contact with the head.

In testimony whereofvl have signed my name to this specification in the presence of two subscribing witnesses.

HENRY LOUIS GUENTHER.

Witnesses HENRY H. UNRUH, MARY E. DU Bors. 

